Multi-Resolution Audio Signals

ABSTRACT

An apparatus including at least one microphone; audio circuitry connected to the at least one microphone; and a memory connected to the audio circuitry. The audio circuitry is configured to output a first audio track and at least one second audio track. The audio circuitry is configured to form the first audio track from an output signal, provided by the at least one microphone, by processing the output signal with a first audio configuring, and where the audio circuitry is configured to form the at least one second audio track from the output signal, provided by the at least one microphone, without the first audio configuring. The memory is configured to store the first audio track and the at least one second audio track together.

CROSS REFERENCE TO RELATED APPLICATION

This is a continuation application of copending application Ser. No. 13/669,932 filed Nov. 6, 2012 which is hereby incorporated by reference in its entirety.

BACKGROUND Technical Field

The exemplary and non-limiting embodiments relate generally to multi-resolution audio signals and, more particularly, to audio signals where the audio signals have different audio resolutions.

Brief Description of Prior Developments

In some devices, such as a conventional smartphone for example, audio recording settings are fixed. Thus, audio resolution (sampling rate and dynamic range) of recorded audio is fixed. In this type of conventional smartphone, playing of audio signals is limited to the same resolution as the recording resolution, such as only 16 bit dynamic range and 48 kHz sample rate.

SUMMARY

The following summary is merely intended to be exemplary. The summary is not intended to limit the scope of the claims.

In accordance with one aspect, an apparatus comprises at least one microphone; audio circuitry connected to the at least one microphone; and a memory connected to the audio circuitry. The audio circuitry is configured to output a first audio track and at least one second audio track. The audio circuitry is configured to form the first audio track from an output signal, provided by the at least one microphone, by processing the output signal with a first audio configuring, and where the audio circuitry is configured to form the at least one second audio track from the output signal, provided by the at least one microphone, without the first audio configuring. The memory is configured to store the first audio track and the at least one second audio track together.

In accordance with another aspect, a method comprises recording a first audio track on a memory, where the first audio track comprises an output signal provided by a microphone which has been processed with a first audio configuring; and recording at least one second audio track on the memory with the first audio track, where the at least one second audio track comprises the output signal provided by the microphone which has not been processed with the first audio configuring.

In accordance with another aspect, a non-transitory program storage device readable by a machine is provided, tangibly embodying a program of instructions executable by the machine for performing operations, the operations comprising recording a first audio track on a memory, where the first audio track comprises an output signal provided by a microphone which has been processed with a first audio configuring; and recording at least one second audio track on the memory with the first audio track, where the second audio track comprise the output signal provided by the microphone which has not been processed with the first audio configuring.

In accordance with another aspect, an apparatus comprises a player configured to play sound from an audio track; and a selector configured to select the audio track to be played by the player from a plurality of audio tracks of a same recorded sound. Each of the plurality of audio tracks has a different audio configuring of the same recorded sound, where the selector is configured to select the audio track to be played based, at least partially, upon an ability of the player to properly play the audio configuring of the audio track.

In accordance with another aspect, a non-transitory memory device comprises a first audio track having a first output signal, provided by at least one microphone, which has been processed with a first audio configuring to thereby have a first audio configuration; and a second audio track in a same file as the first audio track, where the second audio track has a second output signal, provided by the at least one microphone, which has not been processed with the first audio configuring to thereby have a second different audio configuration.

BRIEF DESCRIPTION OF THE DRAWINGS

The foregoing aspects and other features are explained in the following description, taken in connection with the accompanying drawings, wherein:

FIG. 1 is a front view of an example embodiment of an apparatus;

FIG. 2 is a diagram illustrating some of the components of the apparatus shown in FIG. 1;

FIG. 3 is a diagram illustrating some of the components of the audio circuitry;

FIG. 4 is a diagram illustrating some method steps in an example embodiment;

FIG. 5 is a diagram illustrating a user interface in an example embodiment;

FIG. 6 is a diagram illustrating a user interface in an example embodiment;

FIG. 7 is a diagram illustrating a user interface in an example embodiment;

FIG. 8 is a diagram illustrating some steps of an example method;

FIG. 9 is a diagram illustrating one type of example of an electronic file having tracks with different audio resolution of a same sound recording; and

FIG. 10 is a diagram illustrating how the file of FIG. 9 may be used with different devices having players with different audio resolution playing capabilities.

DETAILED DESCRIPTION OF EMBODIMENTS

Referring to FIG. 1, there is shown a front view of an apparatus 10 incorporating features of an example embodiment. Although the features will be described with reference to the example embodiments shown in the drawings, it should be understood that features can be embodied in many alternate forms of embodiments. In addition, any suitable size, shape or type of elements or materials could be used.

The apparatus 10 may be a hand-held communications device which includes a telephone application, such as a smartphone for example. The apparatus 10 may also comprise an Internet browser application, camera application, video recorder application, music player and recorder application, email application, navigation application, gaming application, and/or any other suitable electronic device application. Referring to both FIGS. 1 and 2, the apparatus 10, in this example embodiment, comprises a housing 12, a display 14, a receiver 16, a transmitter 18, a rechargeable battery 26, and a controller 20. The receiver 16 and transmitter 18 form a wireless mobile communication interface to allow the apparatus 10 to communicate with a wireless telephone system, such as a mobile telephone base station for example. As seen in FIG. 2, the controller 20 may include at least one processor 22, at least one memory 24, and software. However, all of these features are not necessary to implement the features described below. It is also noted that features as described herein are not limited to wireless telephone systems. For example, features as described may be used with a video camera or a non-wireless audio recorder or player.

The display 14 in this example may be a touch screen display which functions as both a display screen and as a user input. However, features described herein may be used in a display which does not have a touch, user input feature. The user interface may also include a keypad (not shown). The electronic circuitry inside the housing 12 may comprise a printed wiring board (PWB) having components such as the controller 20 thereon.

The circuitry includes at least one microphone(s) 28, an earpiece speaker 30, and perhaps also a sound speaker 32, such as at the rear side of the apparatus 10. As shown in FIG. 2, the circuitry includes audio circuitry 34 which is connected to the microphone(s) 28 and the speaker(s) 30, 32. Referring also to FIG. 3, the microphone 28, in this example, comprises a sound transducer which produces an audio signal 42 based upon incoming sound 44. The audio circuitry includes a microphone driver 38, and circuitry for hardware specific processing 40. In this non-limiting example the microphone driver is the hardware driver for the microphone(s), usually consisting of a digital decimator for digital microphones and outputting a Pulse Code Modulation (PCM) word of desired accuracy (such as 16-bit or 20-bit or 24-bit for example) into a hardware buffer(s), which is read by associated driver software. The hardware specific microphone processing may do purely hardware specific processing such as, for example, a microphone equalizer to ensure that the frequency response of the microphone(s) is as flat as possible with the product acoustics.

Referring now also to FIG. 4, the circuitry and software are adapted to perform hardware independent processing of the audio signal 42 or 43 from the microphone(s) 28 (or on the signal after processing by the microphone driver 38 or hardware processing 40). In this non-limiting example, the apparatus may be programmed to determined if raw microphone audio 42 is to be recorded as indicated by block 46. If YES, the apparatus may be programmed to determined if the raw microphone audio signal 42 should be encoded as indicated by block 48. The audio encoding 50 may comprise, for example, AAC, WMA, MP3, FLAC, and/or Dolby Digital Plus. The apparatus may be programmed to perform Muxing or file writing as indicated by block 52, to the memory 24 for example or another recordable medium. File writing and possible muxing do writing of the data to a file (in case of muxing together with no-audio data such as video and/or combining multiple audio signals into a single container).

In addition to possibly recording the raw microphone audio, the apparatus may be programmed to perform generic audio recording processing as indicated by block 54. For example, generic audio recording processing may comprise quality improvements such as wind noise reduction or other noise reduction, such as microphone self-noise reduction.

In addition to possibly performing generic audio recording processing 54, the apparatus may be programmed to determine, as indicated by block 56, if the audio is to be recorded before possible application audio recording processing as indicated by block 58. If YES, the apparatus may be programmed to determined if the audio signal after generic audio recording processing 54 should be encoded as indicated by block 48.

If the audio is to be recorded with possible application audio recording processing as indicated by block 58, the application audio recording processing may use case specific processing such as upmixing or audio zooming for example. The apparatus may be programmed to determined if the audio signal after application audio recording processing 58 should be encoded as indicated by block 48.

With features as described herein, more than one variations of an audio signal (as identified before any possible encoding 50) may be recorded together in a common file, perhaps as separate audio tracks. In the example shown, five possible variations include:

-   -   Pure microphone data 42. Non-processed microphone data is         recorded.     -   Raw audio data 43. No other processing other than microphone         hardware specific processing is done (e.g. microphone         equalizer).     -   Data 60 after minimalistic processing in 54. This includes         generic processing that most users would want to be done such as         wind noise reduction for example.     -   Data 62 after quality improvements from 56. This includes         further quality related processing such as street noise         reduction has been done.     -   Data 64 after application processing from 58. This includes         application related processing such as, for example, upmixing to         5.1 has been done.

Audio resolution, as used herein, refers to the dynamic range and sample rate (frequency range) of an audio signal. Dynamic range refers to a difference between the quietest and loudest audio. Conventional microphones can record about 87 dB dynamic range (microphone self-noise limits to 33 dB SPL and distortion limits to 120 dB SPL) for which 16-bit audio, corresponding to 96 dB dynamic range, is adequate. It is believed that the audio recording path in most smartphones using conventional microphones is targeted for 16-bit dynamics.

However, newer microphone technology that is already in use in certain devices, have lower self-noise (such as 27 dB SPL for example) and the ability to have high amplitude audio capture such as at 140 dB, thus having an expanded dynamic range of 113 dB. With the new microphone technology, to capture the whole dynamic range, arithmetics larger than 16-bit is needed. In some smartphones using the newer microphone technology, software processing is used on the dynamics to compress the dynamic range to 16 bits to better match normal listening room conditions.

Features as described herein allow multiple audio tracks to be recorded with different resolution settings of dynamic range and/or frequency range to a same file. Also, audio data may be taken from different places in the audio capture processing chain (see FIG. 4). Also, different tracks can be encoded with different audio codecs or not coded at all (i.e. raw audio data capture).

Benefits include that one track would be suitable for all rendering devices and would utilize conventional settings. Other track(s) would use higher ranges and could be used by more advanced applications or rendering devices.

The audio recording path in a conventional recording device, such as a smartphone for example, has been designed so that it suites the needs of normal everyday usage. Frequency range is (almost) good enough for sounds that are heard by human ear in the first place. Also dynamic range captures (almost) everything that people would find useful. However, there is information beyond the conventional 24 kHz frequency range (48 kHz sample rate) and conventional 16-bit dynamic range. Thus, use of the new microphone technology is now desirable. However, audio recording are commonly used or shared on multiple different devices. For example, a first person might want to share an audio/video file taken with a smartphone with a second person's smartphone. If the first person's smartphone records the audio/video file at an audio resolution larger than 48 kHz sample rate and 16-bit dynamic range using the new microphone technology, and if the second person's smart phone is older and does not have the capability to play audio having a resolution larger than 48 kHz sample rate and 16-bit dynamic range, the audio component of the file cannot be played by the second person's smartphone.

High quality audio recording uses 48 kHz sampling rate to ensure the whole human audible frequency range from 20 Hz to 20 kHz can be captured. According to Nyquist sampling theorem, it is possible to capture half of the sampling rate accurately, but this presumes a brick-wall low-pass filter at the sampling frequency. With 48 kHz, the 20 kHz is well captured and the LP-filter can be more relaxed.

Analog-to-digital and digital-to-analog converter chips are now available with higher sampling rates, such as 96 kHz and 192 kHz. These high sampling rates do capture content higher than it is possible for a human to hear. But there are some claims that e.g. the high-energy transients are better captured with higher than Nyquist sampling rates.

In the example shown in FIG. 1, the apparatus 10 is configured to allow the user to select audio resolution for at least one track of the recorded sound by use of the user input touch screen 14. FIG. 5 shows a portion of an example user interface. In this example, there are settings for multiple tracks (only two are fully visible in this example). For each track the user can select the dynamic range and sample rate. Realistic values of 16, 20 and 24 bits and 48, 96 and 192 kHz have been selected, but features as describe herein are not limit to these.

When it comes to dynamic range, the user interface (UI) can show the values also in decibels indicating either the theoretical maximum of that word length or what the real dynamic range would be with the microphones used in that specific product. A similar approach may be used for the sample rate.

The apparatus 10 is configured to take a high resolution audio signal from the microphone(s) 28 and lower the resolution to a lower resolution audio signal. The apparatus 10 may use, for example, downsampling of the sample rate and/or dynamic range lowering such as using compression for example. Different example embodiments and methods may be configured to perform this resolution lowering function at any point along the audio signal chain between the microphone and the muxing/file writing. The apparatus may be configured to record a higher resolution audio signal and a lower resolution audio signal of a same sound from a same microphone in one file (perhaps as different tracks). The apparatus may be configured to record a higher resolution audio signal and a lower resolution audio signal of different sounds from respective different microphones in one file (perhaps as different tracks) or perhaps in different files. The apparatus may be configured to record a higher resolution audio signal and a lower resolution audio signal of different sounds from a same microphone in one file (perhaps as different tracks) or perhaps in different files. One example is audio zooming using different parameters, but still using the same microphone(s).

FIG. 6 shows a portion of an example user interface to enable a user to select additional recording settings. There are settings for multiple tracks (only the first one is fully visible). For each track the user may select the point in the recording processing chain from where audio will be recorded. The points and their terminology are examples only. Here they represent the following:

-   -   Pure microphone data means that non-processed microphone data is         recorded.     -   Raw audio data means that no other processing than microphone HW         specific processing is done e.g. microphone equalizer.     -   Minimalistic processing means that also generic processing that         most users would want to be done like wind noise reduction is         done.     -   Quality improvements means that further quality related         processing like street noise reduction is done.     -   Application processing means that application related processing         like upmixing to 5.1 is done.

FIG. 7 shows a portion of an example user interface to enable a user to select additional recording settings. There are settings for multiple tracks (only the first one is fully visible). For each track the user may select the used encoder.

Examples of use cases for non-conventional dynamic range include:

-   -   20-bit: e.g. 4-bit headroom for 3rd party audio application         processing related to e.g. equalization or dynamics compression     -   24-bit: super quality audio compatible with expensive high-end         home audio reproduction systems. Accurate representation for         measurement applications, such as a dB-meter or a frequency         analyzer.

Examples of use cases for non-conventional frequency range include:

-   -   96 kHz sample rate: One can record what dogs hear and also         decimate that to audible frequencies.     -   192 kHz sample rate: One can record most of what bats emit and         also decimate that to audible frequencies.

With features as described herein, a new use case for higher sampling rates is ultrasonic audio, which could be used e.g. to capture a pen movement or unaudible animal sounds.

FIG. 9 shows one example embodiment of an audio file (or audio component of an audio/video file) 70 with multiple tracks 70 a-70 g where each track is made from the same sound 44 received at the microphone(s) but each has a different audio resolution. Of course, in an alternate example more or less than 5 tracks could be provided. The player, such as in apparatus 10 or another apparatus, which plays the audio file 70 can be configured to automatically play the track 70 a or 70 b or 70 c or 70 d or 70 e which the player is most compatable with. Alternatively, or additionally, the player may allow the user to select the track 70 a-70 e which the user wants to play. One or more of the tracks may have a signal which has been downsampled and/or dynamic range lowered, and/or different encoding as indicated by 70 f and 70 g.

Features of the example embodiment relate to recording audio with higher than conventional sample rate and dynamic range (i.e. higher than 48 kHz sample rate and 16-bit word length). At least two audio tracks may be recorded into one container/file. A first one of the tracks may follow the current de facto parameters for good audio recording (i.e. 48 kHz sample rate and 16-bit word length). In an alternate example, the first track might not follow the current de facto parameters. The other track(s) may have a relatively bigger sample rate and/or a bigger dynamic range (i.e. bigger than the conventional 48 kHz sample rate and 16-bit word length). The rendering device may then render the best quality track it can (the first track or one of the other tracks). The default track would in practice be the one with conventional quality settings (i.e. 48 kHz sample rate and 16-bit word length). In an alternate example embodiment the default track might not be the first track in the container (e.g., MP4).

In one type of example, a non-transitory memory device, such as memory 24 or medium 98 (see FIG. 10) for example, may comprise a first audio track (70 g) having a first output signal, provided by at least one microphone, which has been processed with a first downsampling and/or range lowering to thereby have a first audio resolution; and a second audio track (70 c) in a same file (70) as the first audio track, where the second audio track has a the first output signal or a different second output signal, provided by the at least one microphone, which has not been processed with the first downsampling and/or range lowering to thereby have a second different audio resolution.

Referring also to FIG. 10, the apparatus 10 has a player 80 for playing audio, such as including the speaker(s) 30, 32. In a first example the player 80 has limitations regarding how high an audio resolution can be played. In this first example it may be able to play only a limited audio resolution of 48 kHz sample rate and 16-bit dynamic range. The apparatus 10 includes a selector 82, such as part of the controller 20, which is configured to automatically select the audio track to be played by the player 80 from a plurality of audio tracks (such as 70 a, or 70 b, or 70 c, or 70 d, or 70 e, or 70 f, or 70 g, etc. for example) of a same recorded sound. The selection may be based upon the audio resolution playing capability of the player 80.

In this first example, even though the player 80 of the apparatus 10 cannot play the higher audio resolution tracks in the file 70, the apparatus is still able to record the file 70 with one or more tracks having an audio resolution higher than the audio resolution playing capability of of the player 80 (48 kHz sample rate and 16-bit dynamic range).

The file 70 may be shared with other devices 90 a, 90 b, 90 c, such as via links 94, 96, 98. Thus, audio tracks captured by the apparatus 10 may be rendered by another apparatus. In one use case, the whole media container may be sent. For example, a media container may be sent over a wireless DLNA to a home theater system (the home theater system being one of the devices 90 a, 90 b, 90 c for example) and rendered by the home theater system. The links may comprise, for example, an electrical conductor or cable 94, a wireless link 96, or a storage device or medium 98 for example. Thus, even though the player 80 of the apparatus 10 might not be able to play the higher audio resolution tracks, other devices might be able to do so.

In a second example, the player 80 is configured to play a higher audio resolution of 192 kHz sample rate or less and a 24-bit dynamic range or less. The player 80 can, thus, play any one of the tracks 70 a-70 g. However, the player 92 b of the device 90 b is only able to play a limited audio resolution of 48 kHz sample rate and 16-bit dynamic range, and the player 92 c of the device 90 c is only able to play a limited audio resolution of 96 kHz sample rate or lower and a 20-bit dynamic range or lower. In this case, the same file 70 can still be used by any of the devices 10, 90 a, 90 b, 90 c because the file 70 has different tracks of the same sound recording which has been recorded at the various different audio resolutions; where at least one of the tracts may be subsequently played by the devices.

In one example embodiment an apparatus 10 comprises at least one microphone 28; audio circuitry 34 connected to the at least one microphone, where the audio circuitry is configured to output a first audio track (42, 43, 60, 62, 64) and at least one second audio track (42, 43, 60, 62, 64), where the audio circuitry forms the first audio track from an output signal provided by the at least one microphone by downsampling and/or lowering a dynamic range of the output signal with a first downsampling and/or range lowering, such as to a 16-bit dynamic range, and where the at least one second audio track is formed from the output signal provided by the at least one microphone without the first downsampling and/or range lowering; and a memory connected to the audio circuitry which is configured to store the first audio track and the at least one second audio track together. “Together” may include a same file or different files, so long as they are in a same memory or a same storage device, such as a single memory or multiple memories in the apparatus or on another recording medium. The first and the second tracks do not need to be saved in same tracks following each other, and the first and second tracks do not need to be saved as parallel played tracks, such as stereo (i.e. one file comprising left and right channels). The tracks may be independently saved in a memory(ies) where each saved track may be independently selected/accessed later.

The apparatus may be configured to store the first audio track and the at least one second audio track in the memory in a common file. The first dynamic range lowering may lower the audio signal to a dynamic range of about 20 bits or 16 bits. The first downsampling may lower the audio signal to a sample rate of about 96 kHz or 48 kHz. The output signal from the microphone may be processed by the microphone with a microphone driver and hardware specific microphone processing. The audio circuitry 34 may comprise a processor and audio processing software. The audio circuitry may be configured to perform audio processing on the audio signal to form the first audio track comprising noise reduction, upmixing, audio zooming, and/or audio encoding. The audio circuitry may be configured to perform audio processing on the audio signal to form the at least one second audio track comprising noise reduction, upmixing, audio zooming, and/or audio encoding. The audio circuitry may be configured to form at least one of the second audio tracks without any compression or downsampling. The audio circuitry may be configured to form at least one of the second audio tracks with a second compression and/or downsampling which is different from the first compression and/or downsampling. The apparatus may further comprise a selector configured to automatically select one of the audio tracks to be played by the apparatus, where each of the plurality of audio tracks has a different audio resolution of a same recorded sound, where the selector is configured to automatically select the audio track to be played based upon an ability of the apparatus to properly play the audio resolution of the audio track.

Referring also to FIG. 8, an example method may comprise recording a first audio track on a memory as indicted by block 66, where the first audio track comprises an audio signal from a microphone which has been compressed with a first compression; and recording at least one second audio track on the memory with the first audio track as indicated by block 68, where the at least one second audio track comprises the audio signal from the microphone which has not been compressed with the first compression.

The method may comprise recording the first audio track and the at least one second audio track in the memory in a common file. The method may comprise compressing the audio signal to a dynamic range of about 20 bits or 16 bits as the first compression. The method may comprise compressing the audio signal to a sample rate of about 96 kHz or 48 kHz as the first compression. The method may comprise providing a user an ability to select audio resolution of the first audio track including dynamic range and sample rate. The method may comprise providing a user an ability to select audio resolution of at least one of the second audio tracks including dynamic range and sample rate of the at least one second audio track. The method may comprise a selector of an apparatus automatically select the audio track to be played by the apparatus from the audio tracks of a same recorded sound, where each of the audio tracks has a different audio resolution of the same recorded sound, where the selector automatically selects the audio track to be played based upon an ability of the apparatus to properly play the audio resolution of the audio track.

In one type of example embodiment a non-transitory program storage device readable by a machine, such as memory 24 for example, tangibly embodying a program of instructions executable by the machine for performing operations may be provided, where the operations comprise recording a first audio track on a memory, where the first audio track comprises an audio signal from a microphone which has been compressed with a first compression; and recording at least one second audio track on the memory with the first audio track, where the second audio track comprise the audio signal from the microphone which has not been compressed with the first compression.

In one type of example embodiment an apparatus comprises a player configured to play sound from an audio track; and a selector configured to automatically select the audio track to be played by the player from a plurality of audio tracks of a same recorded sound, where each of the plurality of audio tracks has a different audio resolution of the same recorded sound, where the selector is configured to automatically select the audio track to be played based upon an ability of the player to properly play the audio resolution of the audio track.

Features as described herein are not limited to smartphones. Features could, for example, be used in any suitable device having audio recording capability or audio file playing capability.

The description above sometimes refers to different compressions of the “same audio”. However, in some example embodiments and methods different audio tracks of different resolution may have different audio sources. One example would be a zooming to a flying bat with high sample rate, and another audio track zooming to a speaking human object with de facto sample rate. Thus, features as described herein are not limited to “same audio”.

The above description refers to functions being performed with the audio circuitry 34. It should be noted that the term “audio circuitry” is being used very broad here to include any type of electronics which processes an audio signal. Actual audio specific electronic hardware may output (or provide input) which other components may use to render the final maximum resolution and the lower resolution tracks such as made by a processor using software for example. Thus, the dynamic range handling and sample rate handling can be, at least partially, a hardware independent operation. “Audio circuitry” 34 shown in the drawings is intended to include both hardware and software processing of signals, so audio circuitry 34 may include 20 as a part of that circuitry.

The description above describes downsampling and/or dynamic range lowering for compression. However, there may be other means to select lower dynamics than traditional dynamic range compression (DRC). For example, a moving 16-bit window may be used within a 24-bit dynamic range where the 16-bit window is controlled by automatic volume controller. Features as described herein are not limited to traditional compression to select a lower dynamic audio signal from a high dynamic source.

In one type of example embodiment, the audio tracks with different resolutions may end up being in physically separate files. Features as described herein are not limited to having the audio tracks muxed into a single container. In such an example, there would still likely be some logical connection between the separate tracks, such as by means of file naming for example.

Features as described herein relate to capturing multiple audio tracks. Each track may have any sample rate, any word length, and/or be encoded by any codec. The tracks can also be in any order. Good examples are 48, 96 and 192 kHz for sample rate, and 16, 20 and 24 bits for word length, but features as described herein are not limited to these examples.

In one type of example, an apparatus 10 may be provided comprising at least one microphone; audio circuitry connected to the at least one microphone; and a memory. The audio circuitry may be configured to output a first audio track and at least one second different audio track. The audio circuitry may be configured to form the first audio track from an output signal, provided by the at least one microphone, by first audio resolution lowering with first audio resolution lowering settings. The audio resolution lowering may comprise downsampling of the output signal and/or lowering a dynamic range of the output signal. The lowering of the dynamic range of the output signal may comprise compression and/or a moving bit window used within a higher bit dynamic range controlled by an automatic controller for example, such as an automatic volume controller for example. The audio circuitry may be configured to form at least one of the second audio track(s) from the output signal, provided by the at least one microphone, without the first audio resolution lowering. The memory is connected to the audio circuitry which is configured to store the first audio track and the at least one second audio track together; perhaps in a same file.

In one example embodiment, an apparatus 10 comprises at least one microphone; audio circuitry connected to the at least one microphone; and a memory connected to the audio circuitry. The audio circuitry is configured to output a first audio track and at least one second audio track, where the audio circuitry is configured to form the first audio track from an output signal, provided by the at least one microphone, by audio configuring of the output signal with a first audio configuring, and where the audio circuitry is configured to form the at least one second audio track from the output signal, provided by the at least one microphone, without the first audio configuring. The memory is configured to store the first audio track and the at least one second audio track together.

The “audio configuring” may comprise configuring which changes the audio resolution of the output signal such as changing the sampling rate or changing the dynamic range. Changing the sampling rate may comprise, for example, downsampling or upsampling. Changing the dynamic range may comprise, for example, as lowering the range or increasing the range. Thus, upsampling and dynamic range increase are possible applications as well. Such configuring is computational only, but still applicable. An example would be always-on, low-power recording with lower sampling rate and dynamics, which would be upsampled and expanded to meet the de facto audio parameters (16-bit, 48 kHz). So, re-sampling to any arbitrary sample rate and compressing/expanding to any arbitrary dynamic range may be used.

The “audio configuring” may alternatively or additionally comprise audio processing such as described with reference to FIGS. 4, 6 and 7. The “audio configuring” may alternatively or additionally comprise encoding as described with reference to FIG. 4. It may be that downsampling or range lowering is not needed at all if that specific track records the best the HW can offer. Different audio tracks can have the same resolutions if they differ in some other ways; e.g. wind noise reduction enabled/disabled.

Thus, as used herein, a first audio configuring may comprise:

-   -   a first audio resolution (increasing or decreasing sampling         and/or dynamic range, or no changes to sampling and/or dynamic         range) and/or     -   a first audio processing (such as no audio processing,         minimalistic processing, quality improvements or application         processing for example) and/or     -   a first encoding (such as no encoding, AAC, WMA, MP3, FLAC or         Dolby Digital Plus for example),         and a second audio configuring may comprise:     -   a different second audio resolution (increasing or decreasing         sampling and/or dynamic range, or no changes to sampling and/or         dynamic range) and/or     -   a different second audio processing (such as no audio         processing, minimalistic processing, quality improvements or         application processing for example) and/or     -   a different second encoding (such as no encoding, AAC, WMA, MP3,         FLAC or Dolby Digital Plus for example).         However, in this example, the recording apparatus and method         would provide at least two tracks recorded together, in a same         file or separate files, from a sound(s) picked-up by a         microphone(s) at about a same time, where the output provided by         the microphone(s) has some type of different audio configuring         for at least one of the tracks when recorded into the recording         medium.

In one example embodiment the first audio configuring may compress the output signal to a dynamic range of about 20 bits or 16 bits. The first audio configuring may downsample the output signal to a sample rate of about 96 kHz or 48 kHz, for example, or upsample the output signal to a higher sample rate. The audio circuitry may be configured to perform the audio configuring on the output signal to form the first audio track comprising, for example, noise reduction, upmixing, audio zooming, and/or audio encoding. The audio circuitry may be configured to perform second different audio configuring on the output signal to form the at least one second audio track comprising, for example, noise reduction, upmixing, audio zooming, and/or audio encoding. The audio circuitry may be configured to form at least one of the second audio tracks with a second audio configuring comprising a second downsampling (or upsampling) and/or a second range lowering which is different from a first downsampling and/or a first range lowering provided by the first audio configuring. The audio circuitry is configured to form at least one of the second audio tracks with a second audio configuring comprising a second different resampling and/or a second range changing.

In another example, a method comprises recording a first audio track on a memory, where the first audio track comprises an output signal provided by a microphone which has been processed with a first audio configuring; and recording at least one second audio track on the memory with the first audio track, where the at least one second audio track comprises the output signal provided by the microphone which has not been processed with the first audio configuring.

The method may comprise compressing the output signal to a dynamic range of about 20 bits or 16 bits as the first audio configuring. The method may comprise downsampling the output signal to a sample rate of about 96 kHz or 48 kHz as the first audio configuring.

In another example, a non-transitory program storage device readable by a machine is provided, tangibly embodying a program of instructions executable by the machine for performing operations, the operations comprising recording a first audio track on a memory, where the first audio track comprises an output signal provided by a microphone which has been processed with a first audio configuring; and recording at least one second audio track on the memory with the first audio track, where the second audio track comprises the output signal provided by the microphone which has not been processed with the first audio configuring.

In another example, an apparatus comprises a player configured to play sound from an audio track; and a selector configured to select the audio track to be played by the player from a plurality of audio tracks of a same recorded sound, where each of the plurality of audio tracks has a different audio configuring of the same recorded sound, where the selector is configured to select the audio track to be played based, at least partially, upon an ability of the player to properly play the audio configuring of the audio track. The selector may be configured to automatically choose the audio track to be played. The selector may be configured to allow a user to choose the audio track to be played.

In another example, a non-transitory memory device comprises a first audio track having a first output signal, provided by at least one microphone, which has been processed with a first audio configuring to thereby have a first audio configuration; and a second audio track in a same file as the first audio track, where the second audio track has a second output signal, provided by the at least one microphone, which has not been processed with the first audio configuring to thereby have a second different audio configuration.

It should be understood that the foregoing description is only illustrative. Various alternatives and modifications can be devised by those skilled in the art. For example, features recited in the various dependent claims could be combined with each other in any suitable combination(s). In addition, features from different embodiments described above could be selectively combined into a new embodiment. Accordingly, the description is intended to embrace all such alternatives, modifications and variances which fall within the scope of the appended claims. 

1-19. (canceled)
 20. An apparatus comprising: at least one microphone; audio circuitry configured to output a first audio track and at least one second audio track, where the audio circuitry is configured to form the first audio track from at least one output signal, provided by the at least one microphone, with a first audio resolution, and where the audio circuitry is configured to form the at least one second audio track from the same at least one output signal, with at least one second different audio resolution; a memory connected to the audio circuitry which is configured to store the first audio track and the at least one second audio track; and a controller, connected to the memory, configured to allow the apparatus to transmit at least one of the first audio track and the at least one second audio track to a device, where the apparatus is configured with an incapability of the apparatus to play one or more of the at least one second different audio resolution.
 21. An apparatus as in claim 20 where the apparatus is configured to be coupled to the device and, in conjunction with the device, play the one or more of the at least one second different audio resolution only when coupled to the device.
 22. An apparatus as in claim 20 where the apparatus comprises an audio resolution playing capability of the apparatus to play the first audio track having the first audio resolution.
 23. An apparatus as in claim 20 where the apparatus further comprises a wireless transmitter configured to transmit the first audio track and the at least one second audio track to the device.
 24. An apparatus as in claim 20 where the audio circuitry is configured to process the at least one output signal with a first audio configuring comprising the at least one output signal being dynamic range lowered with a first range lowering to a dynamic range of about 20 bits or 16 bits.
 25. An apparatus as in claim 20 where the audio circuitry is configured to process the at least one output signal with a first audio configuring comprising at least one of: the at least one output signal being expanded to a higher dynamic range, and/or the at least one output signal being upsampled to a higher sample rate.
 26. An apparatus as in claim 20 where the at least one output signal from the at least one microphone is processed by the at least one microphone with a microphone driver and hardware specific microphone processing.
 27. An apparatus as in claim 20 where the audio circuitry is configured to perform at least one of: processing the at least one output signal to form the first audio track comprising noise reduction, upmixing, audio zooming, and/or audio encoding, and/or processing the at least one output signal to form the at least one second audio track comprising noise reduction, upmixing, audio zooming, and/or audio encoding.
 28. An apparatus as in claim 20 where the audio circuitry is configured to form at least one of the second audio track(s) without any resampling and/or dynamic range changing.
 29. A method comprising: recording a first audio track on a memory of an apparatus, where the first audio track is formed from an output signal provided by at least one microphone, of sound received at the at least one microphone, which has been processed with a first audio configuring and forms the first audio track with a first audio resolution; recording at least one second audio track on the memory, where the at least one second audio track is formed from the same output signal which has been processed with a different second audio configuring and forms the at least one second audio track with at least one second different audio resolution; and transmitting at least one of the first audio track and the at least one second audio track from the apparatus to a device for rendering by the device, where the apparatus is configured with an incapability of the apparatus to play one or more of the at least one second different audio resolution.
 30. A method as in claim 29 where the apparatus is configured to be coupled to the device and, in conjunction with the device, the apparatus playing the one or more of the at least one second different audio resolution only when coupled to the device.
 31. A method as in claim 29 where the apparatus comprises an audio resolution playing capability of the apparatus to play the first audio track having the first audio resolution, and the method further comprises the apparatus playing the first audio track without being coupled to the device.
 32. A method as in claim 29 where the apparatus further comprises a wireless transmitter configured to transmit the first audio track and the at least one second audio track to the device, where the transmitting comprises wirelessly transmitting the first audio track and/or one or more of the at least one second audio track to the device.
 33. A method as in claim 29 further comprising the audio circuitry processing the at least one output signal with the first audio configuring comprising the at least one output signal being dynamic range lowered with a first range lowering to a dynamic range of about 20 bits or 16 bits.
 34. A method as in claim 29 further comprising the audio circuitry processing the at least one output signal with the first audio configuring comprising at least one of: the at least one output signal being expanded to a higher dynamic range, and/or the at least one output signal being upsampled to a higher sample rate.
 35. A method as in claim 29 where the at least one output signal from the at least one microphone is processed by the at least one microphone with a microphone driver and hardware specific microphone processing.
 36. A method as in claim 29 where the audio circuitry performs at least one of: processing the at least one output signal to form the first audio track comprising noise reduction, upmixing, audio zooming, and/or audio encoding, and/or processing the at least one output signal to form the at least one second audio track comprising noise reduction, upmixing, audio zooming, and/or audio encoding.
 37. A method as in claim 29 where the audio circuitry forms at least one of the second audio track(s) without any resampling and/or dynamic range changing.
 38. A non-transitory program storage device readable by an apparatus, tangibly embodying a program of instructions executable by the apparatus for performing operations, the operations comprising: recording a first audio track on a memory of the apparatus, where the first audio track is formed from an output signal provided by at least one microphone, of sound received at the at least one microphone, which has been processed with a first audio configuring and forms the first audio track with a first audio resolution; recording at least one second audio track on the memory, where the at least one second audio track is formed from the same output signal which has been processed with a different second audio configuring and forms the at least one second audio track with at least one second different audio resolution; and transmitting at least one of the first audio track and the at least one second audio track from the apparatus to a device for rendering by the device, where the apparatus is configured with an incapability of the apparatus to play one or more of the at least one second different audio resolution.
 39. A non-transitory program storage device as in claim where the apparatus is configured to be coupled to the device and, in conjunction with the device, the operations further comprise playing the one or more of the at least one second different audio resolution in conjunction with the device only when coupled to the device. 